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Fiber Optics
Dan O’Brien
Richard Chouinard
Kyle Degrave
• Optical fibers work on the principal of total internal
reflection.
• They can be used to transmit data signals in the
form of light.
• They are used in endoscopes, which transmit an
image using a bundle of optical fibers.
• Pros of optical fiber data networks
– Speed – operate at high speeds
– Bandwidth – large because many wavelengths can be sent down a
single fiber
– Distance – long transmission
– Resistance – resists EM noise
– Maintenance – cheap
•There are several types of optical fiber
Step-Index Multimode Fiber
Graded-Index Multimode Fiber
Single-Mode Fiber
Pictures from: http://www.arcelect.com/fibercable.htm
Dispersion of signal peaks within
a step-index multimode fiber.
Attenuation of signal
peaks within a stepindex multimode fiber.
The difference in optical path length for a
ray traveling down the center of a stepindex multimode fiber vs. a ray traveling
at the critical angle can be derived from
concepts we learned in class.
The number of reflections within the
fiber can be determined from geometry.
This number is proportional to the to
the signal loss within the fiber.
d = L / Cos(θt)
N = d / ( Dia. / Sin(θt) ) +- 1
d = L n (n^2-Sin(θi))^(-1/2)
Θ = 0, d = L
Θ = θcritical, d = L n (n^2-Sin(θi))^(-1/2)
The dispersion of the signal peaks is
related to the difference between the two
distances.
[L n (n^2-Sin(θi))^(-1/2)] – [L]
Critical angle Eq. for optical fiber
θ = arcsin{[1 – (Ncl/Nco)^2]}^0.5
Signal Attenuation
•
•
•
Attenuation caused by absorption, scattering, and bending of fiber
One of the major advantages of fiber optics is the ability to carry
information much longer distance without being “refreshed” or
strengthened.
Better than say, copper wire.
In general, the index of refraction is a
function of frequency or wavelength
Sensitivity: 0.5 – 1000 dB/km
Po/Pi = 10^(-αL/10)
Av = 20 log10(Vs/Vd)
D proportional to wavelength –
larger WL = more dispersion
References
• Optics Hecht
• http://www.arcelect.com/fibercable.htm
• http://www.corning.com/opticalfiber/discovery_center/tut
orials/fiber_101/index.asp
• Journal of Industrial and Technology.
Volume 19, Number 1. November 2002
Wave Plates and Beam
Splitters
By:
Chris Bowyer
Megan Frantz
Zachary Ryan
Wave Plate
Definition
z
A wave plate consists of a carefully adjusted thickness of a
birefringent material such that the light associated with the larger
index of refraction is retarded by a specific amount. Often times 90°
in phase, making a quarter wave plate or 180°, half wave plate.
Wave Plate
Three kinds of waveplates: Low-order, zero-order, and true-order waveplates
Many flavors:
- Octadic Waveplate
- Quarter Waveplate
- Half Waveplate
- Full Waveplate
Materials used to construct waveplate tend to be a calcite or crystal quartz
lattice where extraordinary (perpendicular) index of refraction differs from
ordinary (parallel) refractive index.
Waveplate adds phase shift delta to orthogonal components
δ = π radians if half-waveplate
Flips the polarization of linearly polarized incident light, rotates the
plane of polarization by π/2, also transforms left-circularly polarized
light into right-circularly polarized light
δ = π/2 radians if quarter-waveplate
Transforms linearly polarized light into circularly polarized light,
commonly used in Q-switches and isolators.
r r
r
E = A cos k ⋅ r − ωt = A cos ( kx − ωt ) iˆ + A cos ( ky − ωt ) ˆj
(
)
Wave Plate
Theory
Coherent plane wave propagating in z direction:
r r
r
E = A cos k ⋅ r − ωt = A cos ( kx − ωt ) iˆ + A cos ( ky − ωt ) ˆj
(
)
The two components of the plane wave are in phase
r
E = A cos ( kx − ωt ) iˆ + A cos ( ky − ωt + δ ) ˆj
δ=
2π d ( ne − no )
λi
is the phase shift given by a waveplate where d is the
thickness of the birefringent material, ne is the refractive
index encountered by the extraordinary ray while no is the
refractive index encountered by the ordinary ray, and λi is the incident
wavelength.
Beam Splitter
Definition
z
A Beam Splitter is an optical device that splits a beam of
light.
Beam Splitter
Uses and Theory
z
z
z
The most common form is a cube, made from two
triangular glass prisms which are glued together.
Another design is the use of a half-silvered mirror.
A third version of the beam splitter is a dichroic mirrored
prism assembly which uses dichroic optical coatings to
split the incoming light into three beams, one each of
red, green, and blue.
Beam Splitter
Example
z
Michelson Interferometers
z
Multi-tube colour television cameras
References
z
http://en.wikipedia.org/wiki/Wave_plate
z
http://hyperphysics.phy-astr.gsu.edu/hbase/hph.html
z
http://en.wikipedia.org/wiki/Beam_splitter
z
http://www.cvilaser.com/Common/PDFs/CVI_Waveplate_Optical
_Axis_Markings.pdf
z
http://scienceworld.wolfram.com/physics/WavePlate.html
z
http://www.redoptronics.com/waveplate.html
z
http://www.u-oplaz.com/new/waveplate.htm
These devices are used everyday all across the world to
facilitate data entry into a computer. Originating in the
1970’s, these scanners use several optical concepts to
accomplish this task. So how does this little box organize
all this data from a bunch of little lines?
Let’s find out!
By: Dominic Held, Corey Miller, and Joel Schultz
Laser scanners use a moving pinpoint of light to illuminate the
barcode, and a single photocell receives the reflected light. Most
laser scanners sweep the laser beam horizontally using an
electronically controlled mirror.
The dark lines in the barcode reflect less light. This enables the
photocell to sense differences in the width of the bars.
1. Using mirrors, a HeNe laser
is aimed at a rotating mirror.
2. The rotating mirror reflects
this beam to one of 5
angled mirrors within the
device.
3. The fixed mirrors reflect the
laser beam toward the
awaiting barcode.
4. The barcode reflects back
a portion of this beam,
based on the white and
dark lines.
5. The beam returns to the
fixed mirror, which reflects
the beam back to the rotating
mirror, which sends it back to
the two way spherical mirror.
6. The beam is reflected off
the spherical mirror and
completes its journey at the
sensor
Flat Mirror
The Law of Reflection states that the
angle of incidence equals the angle of
reflection.
θi = θr
Spherical Mirror
The light rays approaching the mirror
from the focal point are reflected parallel
to the principle axis.
References
Adams, Russ. Reading Between the Lines: An Introduction to Bar Code Technology, 4th
ed. Helmers Publishing, Inc., 1989.
Stamper, Bonney. "What Happens When a Scanner Reads a Bar Code?," Industrial
Engineering. October, 1992, p. 34.
Images from:
•
http://www.taltech.com/TALtech_web/resources/intro_to_bc/bcpwork.htm
•
http://www.makebarcode.com/reviews/scanners/lasersketch.html
•
http://www.answers.com/topic/barcode-reader
•
http://farside.ph.utexas.edu/teaching/302l/lectures/node114.html
•
http://www.glenbrook.k12.il.us/gbssci/phys/Class/refln/u13l1c.html
DLP TV
DLP is a cutting-edge optical device used in television and projectors. A
system of lenses, a color filter and millions of mirrors creates a sharp
image.
Rafferty Kelly
Jeremy Bond
Chad Hodgkins
What is DLP?
• Digital Light Processing in TV’s and projection systems
• Light source Converging Lens Color Filter
Converging Lens
Mirrors
Lens
The Digital Micromirror Device
• Each of the microscopic mirrors represents one pixel and
can rotate ± 10°
• Area= 16 µm² (~ 1/5 of human hair)
• Each mirror has a Switched Blazed Grating. This
behaves like a diffraction grating. This controls the
intensity of the light.
• The angle of the mirror will change which fringe
(intensity) is shown.
Color Wheel and Lenses
•
•
Color Filter
– Contains RGB colors
(allows 16.7 million
total colors)
– Spins at 9000 rpm’s
Lenses
– First lens placed 1f
from the color wheel.
– Second Lens placed
close to 1f from the
color wheel to focus
light onto the DMD.
Useful Lens Equations
Used to determine the placement of the color
wheel.
Used to determine the specifications
of the lenses.
Determines the distance between the
shaping lens and the DMD. Also,
determines the distance from the
projector lens to the screen.
References
• Hecht, Eugene. Optics. 3rd ed. Addison-Wesley, New
York, NY. 1998.
• Duncan, Lee, et al. DLP Switched Blaze Grating; the Heart of
Optical Signal Processing. SPIE Proceedings Vol. 4983.
2003.
• Putman, Peter H. Digital Light Processing: A Most
Magical Mirror. Entertainment Design. Vol 34. No. 11.
2000.
• http://www.dlp.com/
• Image:
http://www.audioholics.com/techtips/specsformats/displa
ys_DLP_technology2.html
Holograting
Sarah Mason
Josh Herzog
Stephen Bryant
A hologram is the recording of the interference pattern between a laser
beam, and its reflection from an object. These patterns are captured on
film. When this film is illuminated with a beam of light, the bright and
dark spots on the film act as a diffraction grating producing an image.
How to view
How to make
The E-field when it strikes the film will be the superposition of the N+1 plane waves
The translucency of the film is proportional to the intensity of the light striking it
Substituting in we get
This function represents the opaqueness of the film across the surface.
The third term is responsible for the holography.
Other useful equations
Angle equation
Variables
Fringe separation during exposure
Fringe separation during reconstruction
Diffraction
Interference
References
•
Dr. M. Fogiel, The Optics Problem Solver, Research and Education Association, New
York, N.Y.
•
Robert R. Shannon, The Art and Science of Optical Design, Cambridge University
Press
•
http://ocw.mit.edu/NR/rdonlyres/Media-Arts-and-Sciences/MAS-450HolographicImagingSpring2005/C624ADD2-EF6F-4A7B-8674-1A567EDC8222/0/reflnotes.pdf
•
http://gabriel.physics.ucsb.edu/~jewett/holography_manual_w2002.pdf
•
http://www.economist.com/science/displayStory.cfm?story_id=1956881
Hush
Or the plagues of a thousand angry
curmudgeons will curse you and your
children and your childrens’ children.
Spectrometer
Visualize color, one wavelength at a time
Brian Doozan
Josh Kenealy
Katie McAlpine
General
•
A spectroscope is an optical
device that splits light into
separate wavelengths
– They are able to make very
accurate angle measurements.
•
There are several devices that
can diverge a beam of light
– Diffraction gratings
• Passing light through slits or
reflecting off ridges
– Prisms
• Passing light through a prism of
glass
General
• When a wave passes through a diffraction
grating, light will be diffracted at an angle
proportional to the wavelength.
• This is useful to separate white light into
colors.
• It is used by astronomers to detect which
elements in a star or gas cloud exist.
– Elements each emit a “fingerprint” spectra,
which can be detected with spectroscopy.
Mathematical
1. Grating Equation
sin(α ) + sin(β ) =10−6 mNλ
⎛ β +α ⎞ ⎛ β −α ⎞
−6
2 sin ⎜
⎟ = 10 mNλ
⎟ cos⎜
⎝ 2 ⎠ ⎝ 2 ⎠
2. Angular Dispersion
dβ 10 −6 mN
=
dλ
cos(β )
Resolving Power
Resolving Power
λ
Na (sin (β ) − sin (α ))
R=
= mN =
(∆λ )min
λ
Precision
•
•
•
First Spectroscopes contained
prism or grating in which the
sample was placed and the
observer saw the visible lines.
Pro’s: Can find visible lines in
the visible spectrum. Can
precisely measure the length
of the visible spectrum leading
to what we have today. Able
to discover characteristic
wavelengths of elements.
Con’s: Only good for the
visible spectrum.
Precision
• Next step was the Spectrograph that used photographic
film. User simply placed an exposed camera at the eye
piece of the instrument.
• The longer the exposure of the film the more information
that was collected from the test sample.
• Able to use this for other spectrums( microwave, radio,
and audio frequencies) using a diffraction grating.
• Pro’s: more accurate in details for the characteristic line
spectrum for elements.
Precision
•
•
•
•
Spectrometers today use
electronics (i.e.
photodetector's). Coupled with
a computer we can get a more
accurate spectrograph of the
test sample.
This improved the accuracy of
the spectrometer greatly.
Eye piece is replaced by
CCD’s (charged-couple
devices) improving the
spectrographic analysis.
Pro’s: Spectrometers are
scaled down in size while still
being accurate.
380 - 740 nm
References
•
•
•
•
•
•
•
•
www.jobinyvon.com
http://library.thinkquest.org/21008/data/sky/observatories3.htm#CCD
http://en.wikipedia.org/wiki/Spectrometer
http://library.thinkquest.org/21008/data/sky/spectroscopy3.htm
http://www.telatomic.com
http://www.instrumentssa.com/usadivisions/OOS/oos1.htm
Hecht, Eugene. Optics. Addison Weley: San Francisco, 2002.
Tarasov, Konstantin. The Spectroscope. Wiley: New York, 1974.